DE102008014243A1 - Automotive rotary pump for engine cooling oil has partition rotors whose pressure varies with direction of rotation - Google Patents

Abstract

An automotive rotary pump for engine cooling oil has a pump chamber sub-divided by rotating spring-mounted partition rotors forming oil cells. Each cell has a suction side and an expulsion side. Each partition rotor presses against the cell wall. The pressure applied varies with the direction of rotation.

Description

The The invention relates to a vane pump with a rotor which is rotatably arranged within a stroke contour is and drives at least one wing, to suck on a suction side of a viscous medium, the on a suction Pressure side is pressurized. The invention relates to Further, a method of operating a vane pump described above.

task The invention is a vane pump according to the generic term of claim 1, which has a wide temperature range has a high efficiency.

The Task is with a vane pump with a rotor which is rotatably arranged within a stroke contour and at least one wing drives in order to suck in a viscous medium on a suction side, which is pressurized on a pressure side, solved by that the wing designed and arranged so that the wing depending on the direction of rotation the rotor different degrees or not at the Hubkontur is pressed. The vane pump according to the invention is preferably driven by an electric machine. at The viscous medium is, for example, hydraulic oil. At low temperatures takes the viscosity viscous medium significantly. That causes low temperatures high demands are placed on the electrical machine, which the vane pump drives. In consequence of the high viscosity of the medium, in particular of the fluid, at temperatures at the lower end of the operating range the vane pump, for example, minus 20 degrees Celsius, arise at this operating point very big Friction losses. Due to the wing design according to the invention, the Frictional losses at low temperatures and the associated high viscosity of the medium can be reduced by reducing the wing contact force becomes. The stroke contour is bounded laterally by two side surfaces, the at least one pressure port and at least one suction port exhibit. The rotor is preferably eccentric within the Hub contour arranged. The wing divides a working space of the pump in a pressure chamber and a Suction chamber. Preferably, the vane pump comprises more than one Wing, for example, two wings.

One preferred embodiment the vane pump is characterized in that the wing is guided in the rotor, that the wing in dependence from the direction of rotation of the rotor different degrees with a During operation occurring centrifugal force and acted upon by a spring force becomes. Preferably, the centrifugal force in the one direction of rotation supported by the spring force, and not in the other direction.

One Another preferred embodiment the vane pump is characterized in that in the rotor on a drive shaft provided and the wing assigned drive cam limited circumferentially displaceable is. The drive cam can be integral with the drive shaft connected or as a separate component, for example according to the tongue and groove principle, accomplished be.

One Another preferred embodiment the vane pump is characterized in that between the drive cam and one end of the wing a spring device is arranged. Preferably, the spring device arranged between the drive cam and the associated Flöget that the spring device in one direction of rotation is compressed and in the other Direction of rotation relaxed or acted upon only with a spring biasing force is.

at a method for operating a previously described vane pump the task indicated above is solved by the direction of rotation of the Rotor in dependence from the ambient temperature or the viscosity of the viscous Medium is switched. By reversing the direction of rotation of the rotor can vary the characteristics of the vane pump Ambient temperatures are adjusted. According to one essential aspect The invention provides a pump concept that is suitable for the large spectrum takes into account the occurring medium properties. By reversing the Direction of rotation of the vane pump becomes the characteristic of the Flögelzellenpumpe customized.

One preferred embodiment of the method is characterized in that the suction side and the pressure side of the Flögelzellenpumpe through a hydraulic valve device to be switched. This will the reversal of the direction of rotation of the rotor accounted.

One Another preferred embodiment of the method is characterized in that the suction side and the pressure side of the rotor to be switched by a 4/2-way valve device. Such a directional control valve device has in the context of the present Invention proved to be particularly advantageous.

A further preferred embodiment of the method is characterized in that a switching position of the hydraulic valve device for low temperatures is switched to active. Preferably, the switch position is active for the rather rare operation at low temperatures, For example, via an electromagnet, switched.

One Another preferred embodiment of the method is characterized in that a switching position for one Continuous operation of the vane pump by a return spring device is switched. Preferably, the consumption-relevant continuous operation switched lossless at normal ambient temperatures via a return spring or realized.

The The invention further relates to a manual transmission, in particular a dual-clutch transmission, with a vane pump described above, operated in particular by a method described above becomes. The manual transmission is preferably a parallel shift transmission. According to one essential aspect of the invention is the contact pressure of the wing of the Vane pump in the case of a relatively high viscosity of the medium or fluid to be delivered reduced. A mechanism inside the rotor, also called impeller is designated, causes in a reversal of the direction of rotation of the Pump a reduced contact pressure of the wings to the stroke contour of the housing Pump. By this measure may be the requirement for the power of the driving electrical Machine can be reduced so far that this operating point is not critical becomes.

at the vane pump according to the invention it is preferably a cooling oil pump, the supply a wet-running dual-clutch transmission with cooling oil used and is driven by an electric machine. As a result of high viscosity the cooling oil at low temperatures, especially at the lower end of the operating range at, for example minus 20 degrees Celsius, results in very large friction losses. To the Cover the entire operating range, which must be as a drive for the vane pump used electrical machine designed for very large electrical power become. The invention provides a pump concept, that the big one Spectrum of occurring fluid properties takes into account. there reversing the direction of rotation of the vane pump causes an adjustment the pump characteristic.

Further Advantages, features and details of the invention will become apparent the following description, with reference to the drawing an embodiment is described in detail. Show it:

1 a schematic representation of a vane pump according to the invention in section and

2 the same vane pump as in 1 during operation in a different direction of rotation.

In the 1 and 2 is a erfindungsgernäße vane pump 1 shown in different directions during operation. The vane pump 1 includes a rotor 3 which has substantially the shape of a circular disk. The rotor 3 is inside a cam ring 4 rotatably arranged. The lifting ring 4 in turn is arranged between two side surfaces of a housing, which can be executed with the lifting ring one or more parts. The inner contour of the cam ring is chosen so that there are two diametrically opposed pump chambers 5 . 6 between the outer circumference of the rotor 3 and the inner surface of the cam ring 4 result. The pump rooms 5 . 6 which also work as the vane pump 1 are each designated with a connection area 7 . 8th in connection.

Distributed over its peripheral surface, the rotor 3 slots 11 . 12 on, in each case a wing 14 . 15 slidably guided. The wings 14 . 15 preferably extend over the entire width of the rotor 3 , As the width of the rotor 3 becomes the extent of the rotor 3 perpendicular to the plane of the 1 and 2 designated.

The rotor 3 has a central recess 18 which has substantially the shape of a through hole having a circular cross section. In the central recess 18 is one end of a drive shaft 20 taken up around a rotation axis 21 rotatable, for example by means of the electric machine, is driven. The drive shaft 20 has two drive cams extending in the radial direction 24 . 25 on, which are arranged diametrically. The drive cams 24 . 25 each protrude into a recess 28 . 29 in the central recess 18 is omitted.

The recesses 28 . 29 each have the shape of a groove perpendicular to the plane of the 1 and 2 extends. From one of the flanks of the groove 28 . 29 each one of the slots goes 11 . 12 out. The slots 11 . 12 run, based on the central recess 18 , in tangential direction to the outside. Here are the two slots 11 . 12 arranged parallel to each other. However, the two slots are lost 11 . 12 from the central recess 18 in opposite directions. Between the drive cam 24 . 25 and the associated end of the wing 14 . 15 each is a spring device 31 . 32 arranged.

In 1 the drive shaft rotates 20 as if by an arrow 34 is indicated, clockwise. In this direction of rotation are the drive cam 24 . 25 each at the groove flank of the groove 28 . 29 at the end of the wing 14 . 15 gegenü berliegt. In this direction of rotation of the drive shaft 20 is the spring device 31 relaxed.

In 2 the drive shaft rotates 20 as if by an arrow 35 is indicated counterclockwise. In this direction of rotation of the drive shaft 20 become the spring devices 31 . 32 between the drive cams 24 . 25 and the associated ends of the wings 14 . 15 pressed together. It will be in operation on the wings 14 . 15 acting centrifugal force by the spring force of the spring devices 31 . 32 supported. This leads to a relatively strong contact pressure of the outer ends of the wings 14 . 15 to the lifting ring 4 , In contrast, the in 1 Clockwise rotation shown only a small contact pressure of the outer ends of the wings 14 . 15 to the lifting ring 4 or the housing instead. In 1 It is implied that even a certain play between the outer ends of the wings 14 . 15 and the cam ring 4 can be present.

At low temperatures, that is, at a high viscosity of the cooling oil, the friction losses, as in 1 is indicated by a low contact pressure of the wings 14 . 15 or an enlargement of the existing gap between the wings 14 . 15 and the housing 4 minimized. In this case causes a rotation of the drive shaft 20 clockwise 34 opposite the rotor 3 , which is also referred to as impeller, a discharge of the interposed spring devices 31 . 32 and thus a reduction of the contact pressure. As this operating point in operation with the vane pump 1 equipped motor vehicle rarely and occurs only briefly, the resulting volumetric efficiencies are of minor importance. However, it is ensured that a minimum cooling oil flow, which is about 10 percent of the maximum cooling oil flow, is maintained.

After the viscosity of the fluid, in particular of the cooling oil, has been reduced to an uncritical value due to heating, the direction of the pump can be reversed. In 2 is indicated that the rotation of the drive shaft 20 counterclockwise in the direction of the arrow 35 an additional contact force of the wings 14 . 15 to the lifting ring 4 be as the housing causes, caused by the distortion of the spring devices 31 . 32 is caused.

The rotor 3 , the Hubring 4 and the housing side surfaces (not shown) each bound between the two wings 14 . 15 a displacer whose volume changes as the rotor rotates 3 rotates. This occurs during a rotation of the rotor 3 clockwise 34 , as in 1 is shown in the pump room 6 the vane pump 1 to an increase in volume, the suction of the working fluid in the pump room 6 causes. Therefore, the associated page is also referred to as the suction side. At the same time it comes in the diametrically opposite pump room 5 the vane pump 1 to a volume decrease, the conveying of the working medium from the pump room 6 , which is also referred to as a displacement, causes. As a result, the associated side of the vane pump 1 Also referred to as the print page.

In a reversal of the direction of rotation, the suction side to the pressure side and the pressure side to the suction side, that is at the in 2 indicated direction of rotation 35 becomes the pump room 5 to the suction chamber and the pump room 6 to the pressure room. When reversing the direction of rotation is a switching of the pressure and suction side of the vane pump 1 required. This is realized according to a further aspect of the invention with a 4/2 hydraulic valve. The switching position for the rarely occurring operation at low temperatures is meaningfully active, for example via an electromagnet, switched. The consumption-relevant continuous operation of the vane pump is preferably realized without loss via a return spring.

1

Vane pump

3

rotor

4

lifting ring

5

pump room

6

pump room

7

connection space

8th

connection space

11

slot

12

slot

14

wing

15

wing

18

central recess

20

drive shaft

21

axis of rotation

24

drive cam

25

drive cam

28

recess

29

recess

31

spring means

32

spring means

34

arrow

35

arrow

Claims (10)

Vane pump with a rotor ( 3 ), which within a stroke contour ( 4 ) is rotatably mounted and at least one wing ( 14 . 15 ) is driven to suck on a suction side of a viscous medium which is pressurized on a pressure side, characterized in that the wing ( 14 . 15 ) is designed and arranged so that the wing depending on the direction of rotation ( 34 . 35 ) of the rotor ( 3 ) different degrees or not at all to the stroke contour ( 4 ) is pressed. Vane pump according to claim 1, characterized in that the wing ( 14 . 15 ) is guided in the rotor, that the wing depending on the direction of rotation of the rotor ( 3 ) is acted upon to different degrees with a centrifugal force occurring during operation and with a spring force. Vane pump according to one of the preceding claims, characterized in that in the rotor ( 3 ) on a drive shaft ( 20 ) and the wing ( 14 . 15 ) assigned drive cam ( 24 . 25 ) is limited in the circumferential direction displaced. Vane pump according to claim 3, characterized in that between the drive cam ( 24 . 25 ) and one end of the wing ( 14 . 15 ) a spring device ( 31 . 32 ) is arranged. Method for operating a vane pump ( 1 ) according to the preamble of claim 1, in particular according to one of the preceding claims, characterized in that the direction of rotation ( 34 . 35 ) of the rotor ( 3 ) is switched as a function of the ambient temperature or the viscosity of the viscous medium. A method according to claim 5, characterized in that the suction side and the pressure side of the vane pump ( 1 ) are switched by a hydraulic valve device. A method according to claim 6, characterized in that the suction side and the pressure side of the vane pump ( 1 ) are switched by a 4/2-way valve device. Method according to claim 6 or 7, characterized that a switching position of the hydraulic valve device for deep Temperatures is switched active. Method according to one of claims 6 to 8, characterized in that a switching position for a continuous operation of the vane pump ( 1 ) is switched by a return spring means. Manual transmission, in particular dual-clutch transmission, with a vane pump ( 1 ) according to one of claims 1 to 4, which is operated in particular by a method according to claims 5 to 9.